Classifications

• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04W—WIRELESS COMMUNICATION NETWORKS
  • H04W74/00—Wireless channel access
  • H04W74/08—Non-scheduled access, e.g. ALOHA
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04W—WIRELESS COMMUNICATION NETWORKS
  • H04W74/00—Wireless channel access
  • H04W74/002—Transmission of channel access control information
  • H04W74/004—Transmission of channel access control information in the uplink, i.e. towards network
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04W—WIRELESS COMMUNICATION NETWORKS
  • H04W74/00—Wireless channel access
  • H04W74/002—Transmission of channel access control information
  • H04W74/006—Transmission of channel access control information in the downlink, i.e. towards the terminal
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04W—WIRELESS COMMUNICATION NETWORKS
  • H04W4/00—Services specially adapted for wireless communication networks; Facilities therefor
  • H04W4/70—Services for machine-to-machine communication [M2M] or machine type communication [MTC]
• • H—ELECTRICITY
  • H04—ELECTRIC COMMUNICATION TECHNIQUE
  • H04W—WIRELESS COMMUNICATION NETWORKS
  • H04W74/00—Wireless channel access
  • H04W74/08—Non-scheduled access, e.g. ALOHA
  • H04W74/0833—Random access procedures, e.g. with 4-step access
  • H04W74/0841—Random access procedures, e.g. with 4-step access with collision treatment

Definitions

• Embodiments of the present invention relate to the field of communications technologies, and in particular, to a machine type communication.
• Machine-to-machine communication is a form of data communication involving one or more entities that requires no human intervention.
• the Machine Type Communication (MTC) service introduces a number of new features that differ from, for example, the services provided by current mobile network communications, for example, MTC services are bursty and may involve a potentially large number of communication terminals. , resulting in a surge in communication connections in a short period of time.
• MTC services a potentially large number of communication terminals may attempt to connect to an access network or activate a connection almost simultaneously. For example, consider a typical application - using multiple sensors to monitor a bridge. When vehicles pass through bridges, hundreds or even tens of thousands of sensors may initiate network access at the same time. Or, consider another typical application - meter measurement.
• Thousands of meters in a building may start reporting their measurements or reading results at almost the same scheduled time, such as 12: 00 noon (generally, no precise reporting time is scheduled for each instrument).
• bursty access attempts are likely to collide with each other in the access channel of the access network, even colliding with the normal access attempts of other non-MTC devices that the access network provides services, resulting in the original
• the access channel (e.g., random access channel RACH) of the access network designed for the access attempt of the communication is congested, affecting, for example, normal communication between the conventional user equipments with stricter transmission quality assurance requirements.
• RACH random access channel
• multiple available RACH time-frequency resource configurations are specified for different system bandwidths and for different numbers of cells per base station (or enhanced base station eNB). It can be understood that, by configuring more RACH time-frequency resources in advance, the access of the potential burst MTC device can be adapted, that is, according to The number of MTC access attempts at burst time to configure the system's RACH video resources. Yes, because the MTC device access is bursty, this semi-static resource configuration wastes a lot of uplink resources.
• the uplink resources used to accommodate bursty MTC device access may still be insufficient.
• the number of access time-frequency resources for non-MTC devices has been compared. Large, it is difficult to reserve enough time-frequency resources for the MTC device without affecting the access of non-MTC devices.
• MTC Machine Type Communication
• the MTC device in the cell sends a preamble signal to the base station of the cell to try to perform network access;
• the base station After receiving the preamble signal, the base station sends an access response to the MTC device;
• the MTC device After receiving the access response, the MTC device sends a layer 2/layer 3 message to the base station if the access response does not include the temporary access resource allocation indication, and if the access response includes the temporary access resource allocation indication, Returning to step a, according to the indication, sending a preamble signal by using the allocated temporary access resource to retry network access;
• the base station After receiving the layer 2/layer 3 message, the base station sends a contention determination message to the MTC device; e. after receiving the contention determination message, the MTC device includes the layer 2/ sent by the MTC device in step c after the contention determination message If the content of the layer 3 is included in the message, the network access is completed. If the contention indication message includes the temporary access resource allocation indication, the MTC device returns to step a, and according to the indication, sends the preamble signal by using the allocated temporary access resource. To retry network access; otherwise, the MTC device returns to step a, again using the initially used access resources to send the preamble to retry network access. In this way, the temporary access resources can be quickly allocated to the MTC device according to the severity of the actual collision, thereby avoiding congestion of the access channel.
• steps a and b / between steps d and e are further included:
• the base station performs collision detection according to the preamble signal/layer 2/layer 3 message
• step f If a collision is detected in step f, the base station determines the severity of the collision
• the base station allocates temporary access resources and includes a temporary access resource allocation indication in the transmitted access response/competition decision message.
• the method further comprises the step of: i. after allocating the temporary access resource, if the severity of the collision is reduced below the second collision threshold, the base station stops the allocation of the temporary access resource.
• the base station releases the allocated temporary access resources or a part thereof after the MTC device completes the network access by using the temporary access resources.
• the allocated resources can be dynamically released to avoid waste of uplink resources.
• the preamble signal sent by the MTC device is selected from the preamble subset, and the preamble subset includes all available preambles of the cell.
• the MTC device can learn the subset of the preamble by listening to the system broadcast information sent by the base station.
• the probability of collision between the MTC device and the non-MTC device can be further reduced, and the normal access of the non-MTC device can be protected.
• the invention also proposes a network access system for machine type communication (MTC), comprising: one or more MTC devices in a cell;
• MTC machine type communication
• the MTC device is suitable for:
• the layer 2/layer 3 message is sent to the base station, and if the access response includes the temporary access resource allocation indication, And transmitting, according to the indication, the preamble signal by using the allocated temporary access resource to retry network access;
• the network access After receiving the contention determination message from the base station, if the contention determination message includes the self identity included in the layer 2/layer 3 message sent by the MTC device, the network access is completed; if the contention access message includes the temporary access resource allocation Instructing, the MTC device uses the allocation according to the indication The temporary access resource sends a preamble signal to retry the network access; otherwise, the MTC device uses the initially used access resource to transmit the preamble signal and attempts to access the network.
• the present invention has the following advantages. First, considering the burst characteristics of the access of the MTC device, dynamically allocating (and releasing) the temporary access resources, saving a large amount of uplink resources; second, well protecting the network access of the non-MTC device and avoiding the The impact of the burst of the access of the MTC device; Third, the new access resources are quickly allocated to solve the congestion of the original access channel, and the prior art cannot allocate more resources on the basis of the highest configuration.
• Fig. 1 shows an example of an application environment of the present invention, in which an MTC device, a non-MTC device, and a base station in a cell are schematically shown.
• Fig. 2 schematically shows a network access procedure for MTC in the present invention.
• Fig. 3 schematically shows the allocation of temporary access resources in the present invention. detailed description
• the present invention adopts a dynamic temporary access resource allocation scheme for the bursting of the MTC network access and the large number of accesses, and the collision degree caused by the network access of the MTC device in the cell is relatively serious, for example, causing non- The access channel (eg, RACH) of the MTC device is congested, affecting the temporary access resources available to the MTC device when it affects its normal access operation, and releasing all or part of the collision when the collision level falls below an acceptable level.
• RACH Radio Access Channel
• a subset of the preamble signals used by the MTC device is also set, and the subset is composed of a part of all available preamble signals in the cell, and the MTC device can only select the preamble signal from the subset. Go to the network access attempt. In this way, the collision between the network access of the MTC device and the network access of the non-MTC device can be further reduced.
• the non-MTC device may include any device other than the MTC device, such as a regular user equipment (UE), a terminal device operated by the user to perform access and communication.
• the non-MTC type of communication or access may be any communication or access by a person other than the MTC type of communication or access, for example, may be communication between user equipments as terminals, or between the terminal and the base station. Communication.
• a wireless communication application environment of 3GPP LTE is taken as an example. It should be noted that the embodiments of the present invention are not limited to these applications, but can be applied to more other related communication application environments, such as an application environment including an MTC device.
• the inventors of the present application have noticed that current network service functions, especially mobile network services, are mainly designed for non-MTC services without considering the burstiness of MTC services and the large number of accesses. Therefore, on the basis of current network services, if directly joining the MTC service, channel congestion is likely to occur, affecting, for example, normal communication between legacy user equipments. In order to accommodate this machine type application, some optimizations are needed to support the features of the MTC.
• the access response and the contention determination message in the existing standard are slightly modified to adapt to the access action of the MTC device.
• the MTC device after receiving the access response from the base station, if the access response does not include the temporary access resource allocation indication, the MTC device sends a layer 2/layer 3 message to the base station, if the access response is The temporary access resource allocation indication is included, and according to the indication, the preamble signal is retransmitted by using the allocated temporary access resource to retry network access.
• the MTC device After receiving the contention determination message from the base station, if the contention determination message includes the self identity included in the layer 2/layer 3 message sent by the MTC device, the MTC device completes the network access; if the contention determination message includes the temporary Accessing the resource allocation indication, the MTC device retransmits the preamble signal by using the allocated temporary access resource according to the indication, to retry the network access; otherwise, reusing the preamble signal by using the initially used access resource again, Retry network access.
• the severity of the collision is further determined, and accordingly, whether to allocate the temporary access resource is determined, and if the allocation is decided, the received access response/competition determination message is included.
• Temporary access resource allocation indication so that the MTC device can use the allocated temporary access resources for network access according to the indication.
• FIG. 1 shows an example of an application environment of the present invention, in which an MTC device, a non-MTC device, and a base station in a cell (an enhanced base station eNB in a wireless communication application environment of 3GPP LTE) are schematically illustrated. Only one cell under the eNB is shown in Fig. 1, but this is only for the purpose of clarity of illustration, and the present invention can also be applied to the case where there are multiple cells under each base station. There may be one or more non-MTC devices and one or more MTC devices in the cell.
• the network access process of the MTC device is mainly described below.
• the network access of the non-MTC device may adopt a process or manner well known to those skilled in the art.
• FIG. 2 schematically illustrates a network access procedure for an MTC according to an embodiment of the present invention, wherein a random access manner is taken as an example.
• a random access manner is taken as an example.
• the present invention is not limited to a specific random access method, but can be applied to multiple network access methods.
• the MTC device 20 receives system information of the cell to obtain synchronization with the cell.
• the MTC device 20 transmits a preamble signal to initiate a random access attempt.
• the eNB 10 transmits a random access response (RAR) to the MTC device 20 after receiving the preamble signal.
• RAR random access response
• the MTC device 20 transmits a layer 2/layer 3 message to the eNB 10 upon receiving the random access response.
• the eNB 10 transmits a contention determination message to the MTC device 20.
• the eNB 10 performs collision detection before the eNB 10 transmits the RAR and before the eNB 10 transmits the CRM. If no collision is detected, the random access procedure of the MTC device 20 is substantially the same as the random access procedure for the non-MTC device in the existing standard (eg, 3GPP LTE), where the RAR, Layer 2/Layer 3 messages and The CRM can also use the corresponding message in the existing standard, and the MTC device 20 successfully accesses after step 207, and the access process ends. .
• the existing standard eg, 3GPP LTE
• the eNB 10 detects a collision before performing step 203, specifically, detecting that the MTC device 20 transmits the same preamble signal on the same time-frequency resource simultaneously with the other one or more MTC or non-MTC devices, the foregoing process has Different.
• the existing method for a non-MTC device if the eNB 10 detects a collision before performing step 203, the RAR is not transmitted, and the non-MTC device can know that a collision has occurred, and waits for a certain period of time, such as a time window, and then Perform a random access attempt.
• the eNB 10 when the eNB 10 detects a collision based on the preamble signal at this time, the eNB 10 further detects the severity of the collision, for example, determines whether the severity of the collision exceeds the collision threshold.
• the severity of the collision and the collision threshold may be determined according to the frequency of the collision caused by the random access of the MTC device, the probability, or the number of devices causing the collision according to a predetermined time (for example, in a certain number of frames), It can be set in consideration of the needs of the system or application.
• the collision threshold may be a predetermined value representative of the severity of the collision.
• the value of the collision threshold is variable.
• the value of the collision threshold may change according to the allocation of temporary access resources.
• the collision threshold when the temporary access resource has not been allocated, the collision threshold may be taken as one. Larger value to reduce the probability of false positives for burst access; and when it has been determined that burst access has occurred and temporary access resources are allocated, the collision threshold can be taken A smaller value to effectively reduce the probability of collision in the original access channel.
• the eNB 10 allocates temporary random access resources and includes the temporary random access resource allocation indication in the RAR to be subsequently transmitted.
• the temporary random access resource allocation indication may include an indication of the size and location of the temporary random access resource. For the size and position settings, a variety of options are available.
• the size of the temporary random access resource can be determined according to the severity of the collision. For example, the size may be an integer multiple of a resource unit of a random access resource in a cell configuration.
• the allocated temporary random access resource does not overlap with the original random access resource of the cell, and the location may be adjacent to the original random access resource in each frame, or is not included in each frame.
• the subframe of random access resources as shown in Figure 3.
• the eNB 10 allocates a temporary random access resource, the temporary random access resource will appear in each subsequent frame until it is released.
• the eNB 10 will generate a Temporary Random Access Radio Network Temporary Identifier (temp-RA-RNTI) corresponding to the Temporary Random Access Resource, and will generate The temp-RA-RNTI includes a destination device that combines with the random access preamble signal used at the time of access to identify the RAR message in the RAR to be subsequently transmitted.
• the random access wireless network temporary identifier may be generated in the same manner as the RA-RNTI generating method in the existing standard. That is, the temp-RA-RNTI corresponds to the allocated temporary random access resource. For example, if the current frame includes 10 subframes, the temp-RA-RNTI can be generated as follows:
• temp-RA-RNTI t— t — id+10*t__f— id+1
• t_t_id is the index of the first subframe of the allocated temporary random access resource, 0 ⁇ t_t_id ⁇ 10, t_f_id is the allocated temporary random access in the first subframe The index of the resources, arranged in ascending order in the frequency domain.
• the MTC device 20 After receiving the RAR including the temporary access resource allocation indication, the MTC device 20 is at the step
• the MTC device 20 sends a preamble to initiate a random access attempt.
• the eNB 10 transmits the RAR to the MTC device 20 after receiving the preamble.
• the MTC device 20 sends a layer to the eNB 10 2/layer 3 message.
• the eNB 10 transmits a contention determination message to the MTC device 20.
• the MTC device 20 receives the contention determination message. If a collision occurs, the MTC device 20 reselects the preamble and transmits the reselected preamble with the temporary random access resource to initiate a new random access attempt.
• the eNB 10 does not perform allocation of the temporary random access resources.
• the MTC device 20 re-rans random access using the access resources initially used when transmitting the preamble signal in step 201, like the non-MTC device.
• the eNB 10 Similar to the collision detection in the existing standard, after the eNB 10 receives the layer 2/layer 3 message transmitted by the MTC device 20, collision detection is also performed. Similar to the above description, when the eNB 10 detects a collision according to the layer 2/layer 3 message at this time, the eNB 10 further detects the severity of the collision, and if it is determined that the severity of the collision exceeds the collision threshold, allocates temporary random access resources, and The temporary random access resource allocation indication is included in a contention determination message (CRM) to be subsequently transmitted. As described above, after receiving the CMR, the MTC device 20 initiates a new random access attempt using the allocated temporary random access resources according to the temporary random access resource allocation indication in step 209.
• CMR contention determination message
• the access process of the MTC device that performs network access in a random access manner is described above with reference to FIG.
• the present invention is not limited to the specific flow of the above specific example, and those skilled in the art can understand that the basic idea of the present invention can be applied to other network access involving MTC.
• the eNB 10 may continue to allocate temporary access resources for the new MTC device network access attempt. For two different preamble or time-frequency resource units in which a collision occurs, the same or different temporary access resources may be allocated. As described above, once a temporary access resource is allocated, the temporary access resource will appear in each subsequent frame until it is released. For example, the eNB 10O can maintain a list of all of the temporarily accessed resources allocated and assign those resources to the new MTC device network access attempt that caused the collision.
• the eNB 10 may stop in the RAR or CMR. An indication of the temporary access resource is transmitted, thereby stopping the allocation of temporary access resources to the new MTC network access attempt.
• the eNB 10 can flexibly release all or part of the allocated temporary access resources.
• the threshold value herein may use the foregoing collision threshold, and the value may vary according to factors such as the number of MTC devices that initiate network access attempts, the allocation of temporary access resources, and the like.
• the timer may be set in the eNB 10 according to the characteristics of the specific MTC device. If the timer expires, all the temporary access resources may be determined. The access attempt completes the network access process. At this time, the eNB 10 may release the temporary access resources to save uplink resources. The eNB 10 may also release only a portion of the temporary access resources. When it is decided to release a portion of the temporary access resources, the eNB 10 may continue to allocate the remaining portion of the temporary access resources to the new MTC device network access attempt causing the collision.
• the above considers the collision caused by the MTC device 20, and mainly describes the network access process of the MTC device 20.
• it can use existing network access procedures for network access.
• the eNB 10 detects a collision before performing step 203, it still transmits an RAR, which may include an indication of the temporary access resource. If the non-MTC device receives this RAR, it can directly ignore the indication and prepare for the next access attempt.
• RAR may include an indication of the temporary access resource.
• the non-MTC device can directly ignore the indication and prepare for the next access attempt.
• Another solution is that non-MTC devices can also use temporary access resources for subsequent access attempts. You can choose which solution to use based on the capabilities and preferences of non-MTC devices.
• a dedicated subset of preamble signals may be created for the MTC device 20, the subset may include all available preamble signals for the cell a part of. For example, a certain number of preamble signals (for example, 10) may be selected from all available preamble signals (for example, 64) of the cell according to the non-MTC device load in the cell, and constitute a subset of the preamble signals dedicated to the MTC device 20. For higher non-MTC device loads, a subset including fewer preambles can be set to reduce the likelihood of collisions occurring.
• the subset of preamble signals may be transmitted to the MTC device 20 via system information.
• the MTC device may learn the subset of preamble signals by listening to system broadcast information transmitted by the base station.
• the MTC device 20 can initiate a network access attempt using only the preamble in the subset in step 201.
• the MTC device 20 may select a preamble signal to transmit from the subset of the preamble signals to reduce the possibility of collision occurrence. Sex.
• the preamble signal that can be selected is not necessarily limited to the subset of the preamble signals, but can be selected from all available preamble signals of the cell, because Using temporary access resources for access attempts has reduced the likelihood of collisions.
• the temporary access resource dedicated to the MTC device is allocated, and when the collision severity drops to a certain level, the allocated temporary access resource is released. Therefore, the allocation and release of the MTC access resources can be dynamically performed according to the actual access resource collision status, thereby avoiding waste of uplink resources in the semi-static configuration, and quickly allocating new when the MTC device causes the access channel to be congested. Access resources.
• a dedicated subset of preamble signals is set for the MTC device, which limits the preamble signals that the MTC device can use, further reducing the possibility of collisions and protecting the normal access of non-MTC devices.
• only minor modifications to the existing access procedure such as minor modifications to RAR and CRM messages, and non-MTC devices do not have to change their network access procedures, thus providing good backward compatibility.
• some embodiments also include a machine readable or computer readable program storage device (eg, a digital data storage medium) and encoding machine executable or computer executable program instructions, wherein the instructions perform some of the above methods or All steps.
• the program storage device can be a digital memory, a magnetic storage medium (such as a magnetic disk and magnetic tape), a hardware or an optically readable digital data storage medium.
• Embodiments also include a programming computer that performs the steps of the above method.

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• 2010
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